KR101296554B1 - Drying machine - Google Patents

Abstract

The present invention relates to a dryer, and more particularly, an object of the present invention is to provide a dryer capable of shortening a drying time of a garment by opening and closing the flow channel changing means to select and use the auxiliary heat exchanger of the dryer as an auxiliary evaporator or an auxiliary condenser.

Description

Drying machine

The present invention relates to a dryer, and more particularly, to a dryer that can open and close the flow channel changing means to select and use the auxiliary heat exchanger of the dryer as an auxiliary evaporator or an auxiliary condenser, so that clothes can be dried at a faster time.

The operating principle of the dryer, in particular the clothes dryer, is dehumidified as the internal air of the dryer passes through the evaporator and is changed from the condenser to hot dry air.

The hot, dry air generated as it passes through the condenser is introduced into the dryer's drum via a blower fan.

The hot dry air introduced into the drum of the dryer is changed to wet air again while drying the clothes stored in the drum.

The air, which has changed to a wet state during the drying of clothes, is introduced into the evaporator and dehumidified.

As such, the drying speed of the dryer is very closely related to the temperature and humidity of the air flowing into the drum.

That is, the higher the temperature of the air flowing into the drum and the lower the humidity, the faster the drying speed may be.

In the case of the conventional heat pump type clothes dryer, the temperature of the compressor and the product is low in the initial operation stage, so the refrigeration cycle is operated at low temperature and low pressure, and the temperature and pressure gradually increase over time.

Therefore, it takes a long time to make a high temperature air to dry the clothes effectively, there is a disadvantage that the clothes drying time is long.

The present invention is to solve the above-mentioned disadvantages, the flow path changing means is opened and closed to use the auxiliary heat exchanger of the dryer as a sub-evaporator or a sub-condenser, so that the dryer can dry clothes at a faster time during the initial operation of the dryer The purpose is to provide.

Dryer for solving such a problem,

Compressor for compressing the refrigerant, a condenser connected to the compressor, flow path changing means connected to the condenser, expansion valve and auxiliary heat exchanger and evaporator connected to the flow path changing means,

When the auxiliary heat exchanger is used as an auxiliary evaporator, the refrigerant from the condenser passes through the flow path changing means, passes through the expansion valve, passes through the auxiliary heat exchanger, and then passes through the flow path changing means to flow to the evaporator. When the changing means is opened and closed, and the auxiliary heat exchanger is used as an auxiliary condenser, the refrigerant from the condenser passes through the flow path changing means, passes through the auxiliary heat exchanger, passes through the expansion valve, and then passes through the flow path changing means. The flow path changing means is opened and closed to flow to the evaporator.

The dryer according to the present invention is characterized in that the flow path changing means is on all sides.

In addition, the dryer according to the present invention is characterized in that the refrigerant flow is changed so that the auxiliary heat exchanger is used as an auxiliary evaporator when the dryer is in an initial operation state.

In addition, the dryer according to the present invention is characterized in that the refrigerant flow is changed to measure the drum inlet temperature of the dryer so that the auxiliary heat exchanger is used as an auxiliary evaporator or auxiliary condenser.

According to the dryer according to the present invention has the following advantages.

(1) The auxiliary heat exchanger exchanging heat with the outside may be selected and operated as an auxiliary evaporator or an auxiliary condenser by opening and closing the flow path changing means.

(2) As the temperature of the dryer is low during the initial operation of the dryer, the temperature of the drum inlet rises more quickly by acting as a heat pump that draws heat from the outside by operating the function of the auxiliary heat exchanger as an auxiliary evaporator. It is possible to shorten the time it takes to dry clothes.

(3) Since the auxiliary heat exchanger can be operated by the auxiliary evaporator or the auxiliary condenser by opening and closing the flow path changing means, the drum inlet temperature can be kept constant at the target temperature until the end of drying. It is possible to shorten the time.

1 is a schematic view showing the operation principle of a conventional dryer.
Figure 2 is a block diagram showing a preferred embodiment of the dryer according to the present invention.
Figure 3 is a block diagram showing a preferred embodiment in which the auxiliary heat exchanger is used as a secondary evaporator in the dryer according to the present invention.
Figure 4 is a block diagram showing a preferred embodiment in which the auxiliary heat exchanger is used as a secondary condenser in the dryer according to the present invention.
Figure 5 is a flow chart showing a preferred embodiment of the dryer control method according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

The operating principle of the general dryer will be briefly described with reference to FIG. 1.

The internal air flow cycle in the dryer 10 is as follows.

Low temperature wet air passes through evaporator 100.

After passing through the evaporator 100, the low temperature humid air is dehumidified, and the low temperature air from which the moisture is removed passes through the condenser 40 and is converted into hot dry air.

As such, the air passing through the evaporator 100 and the condenser 40 is moved to the heater 25 by the blowing fan 15 provided in the drum 20.

The air heated by the heater 25 dries the clothes stored in the drum 20, and the air used to dry the clothes is converted into low temperature wet air again.

The low temperature humid air is dehumidified again through the evaporator 100, and the dehumidified low temperature air passes through the condenser 40 and is converted into high temperature dry air used to dry clothes.

The internal air in the dryer 10 will repeat this cycle.

The refrigerant flow cycle in the dryer 10 is as follows.

First, the high temperature low pressure refrigerant evaporated through the evaporator 100 is introduced into the compressor 30 connected to the evaporator 100 and compressed.

The high temperature and high pressure refrigerant flows into the condenser 40 connected to the compressor 30 and the auxiliary condenser 130 connected to the rear end of the condenser, and then emits heat to the surroundings in the process of condensation with the low temperature and high pressure refrigerant.

The auxiliary condenser 130 helps to maintain a constant internal temperature of the drum 20 by controlling the on / off control in the control unit to maintain a constant internal temperature of the drum.

On the other hand, the low temperature and high pressure refrigerant of the liquid phase condensed through the condenser 40 and the auxiliary condenser 130 is introduced into the expansion valve 90 to change into a low temperature low pressure liquid refrigerant, and is introduced into the evaporator (100).

Through the evaporator 100, the low temperature low pressure liquid refrigerant absorbs the surrounding heat and is converted into a high temperature low pressure refrigerant.

Again, the high temperature low pressure refrigerant repeats the cycle flowing to the compressor (30) connected to the evaporator (100).

A flow path (not shown) through which air flows is formed in the drum 20, and the flow path is formed with an inlet port (not shown) for supplying hot dry air into the drum 20.

In addition, the flow path is formed with an outlet (not shown) in which the hot and dry air is converted into humid air by evaporating moisture contained in the clothes, and then introducing the humid air into the refrigerant flow cycle.

Hereinafter, the dryer 10 'by this invention is demonstrated.

The dryer 10 ′ according to the present invention includes a compressor 30 in which a refrigerant is compressed, a condenser 40 connected to the compressor 30, a flow path changing means 60 connected to the condenser 40, and the Including expansion valve 90 and auxiliary heat exchanger 110 and the evaporator 100 connected to the flow path changing means 60,

When the auxiliary heat exchanger 110 is used as the auxiliary evaporator 120, the refrigerant from the condenser 40 passes through the flow path changing means 60, passes through the expansion valve 90, and the auxiliary heat exchanger ( After passing through 110, the flow path changing means 60 is opened and closed to flow through the flow path changing means 60 to the evaporator 100 again.

When the auxiliary heat exchanger 110 is used as the auxiliary condenser 130, the refrigerant from the condenser 40 passes through the flow path changing means 60, passes through the auxiliary heat exchanger 110, and the expansion valve. After passing through 90, the flow path changing means 60 is opened and closed to flow through the flow path changing means 60 to the evaporator 100 again.

For reference, among the configurations of the present invention to be described below, the same configurations as the prior art will be referred to the related art, and a detailed description thereof will be omitted.

The condenser 40 and the flow path changing means 60 are connected to the dryer 10 ′ according to the present invention.

The flow path changing means 60 serves to change the flow of the flow path 50 forming the refrigerant cycle.

An expansion valve 90, an auxiliary heat exchanger 110, and an evaporator 100 are connected to the flow path changing means 60.

The auxiliary heat exchanger 110 is operated as an auxiliary evaporator 120 or an auxiliary condenser 130 according to opening and closing of the flow path changing means 60.

First, the case in which the auxiliary heat exchanger 110 operates as the auxiliary evaporator 120 will be described in detail with reference to FIG. 2.

The refrigerant changed to low temperature and high pressure while passing through the condenser 40 enters the first gate 65 of the flow path changing means.

The refrigerant entering the first gate 65 of the flow path changing means passes through the fourth gate 80 of the flow path changing means.

The refrigerant passing through the fourth gate 80 of the flow path changing means passes through the expansion valve 90.

The refrigerant passing through the expansion valve 90 passes through the auxiliary heat exchanger 110.

At this time, since the auxiliary heat exchanger 110 serves as the auxiliary evaporator 120, it serves as a heat pump that draws heat from the outside.

The refrigerant passing through the auxiliary heat exchanger 110 serving as the auxiliary evaporator 120 enters the flow path changing means 60 through the second gate 70 of the flow path changing means, and then recombines with the flow path changing means. It flows from the flow path changing means 60 to the evaporator 100 through the three gate 75.

As the auxiliary heat exchanger 110 serves as the auxiliary evaporator 120 by opening and closing the flow path changing means 60, the auxiliary heat exchanger 110 acts as a heat pump that draws heat from the outside.

Therefore, since the air heated to some extent by the heat drawn from the auxiliary evaporator 120 moves to the blowing fan 15, it is possible to shorten the time required to make the high-temperature air required for drying.

Next, a case in which the auxiliary heat exchanger 110 operates as the auxiliary condenser 130 will be described in detail with reference to FIG. 3.

The refrigerant changed to low temperature and high pressure while passing through the condenser 40 enters the first gate 65 of the flow path changing means.

The refrigerant entering the first gate 65 of the flow path changing means passes through the second gate 70 of the flow path changing means.

The refrigerant passing through the second gate 70 of the flow path changing means passes through the auxiliary heat exchanger 110.

The refrigerant passing through the auxiliary heat exchanger 110 passes through an expansion valve 90 connected to the auxiliary heat exchanger 110.

The refrigerant passing through the expansion valve 90 enters into the flow path changing means 60 through the fourth gate 80 of the flow path changing means again, and then passes through the third gate 75 of the flow path changing means. Exit from the change means (60).

The refrigerant exiting from the flow path changing means 60 through the fourth gate 80 of the flow path changing means flows to the evaporator 100 connected to the flow path changing means 60.

In this way, the auxiliary heat exchanger 110 can be used as the auxiliary condenser 130 by the flow of the refrigerant according to the opening and closing of the flow path changing means 60, wherein the auxiliary heat exchanger 110 heats the outside. Will be released.

Therefore, when the internal temperature of the drum 20 rises higher than the set temperature, the auxiliary heat exchanger 110 is used as the auxiliary condenser 130 according to the opening / closing of the flow path changing means 60. The temperature can be kept constant.

This not only prevents damage to the clothes during the drying process, but also has the advantage of reducing the risk of fire caused by the use of the dryer.

Hereinafter, another preferred embodiment of the dryer according to the present invention will be described.

By controlling the flow of the refrigerant by using a four-way valve 140 as the flow path changing means 60 for changing the flow of the refrigerant, the auxiliary heat exchanger 110, the auxiliary evaporator 120 or the auxiliary condenser 130 can be used.

Hereinafter, a preferred embodiment of the control method of the dryer according to the present invention will be described.

First, it is determined whether the dryer 10 'is in an initial operation state (S1).

When it is determined in the determination step that the dryer 10 ′ is in an initial operation state, the flow of the refrigerant is changed to use the auxiliary heat exchanger 110 as the auxiliary evaporator 120 (S2).

If it is determined in the determination step that the dryer 10 'is not in the initial operation state, the flow of the refrigerant is changed to use the auxiliary heat exchanger 110 as the auxiliary adapter 130 (S3).

As such, when the flow of the refrigerant is changed and the auxiliary heat exchanger 110 is used as the auxiliary evaporator 120, the auxiliary heat exchanger 110 serves as a heat pump that draws heat from the outside.

As such, since the air inside the drum is partially heated by the auxiliary evaporator 120 serving as a heat pump, the heating time by the heater 25 is shortened.

Therefore, the time for making the hot air required for drying clothes is shortened, so that the time for drying clothes can be shortened.

Hereinafter, a preferred embodiment of the control method of the dryer 10 'according to the present invention will be described.

First, it is determined whether to use the auxiliary heat exchanger 110 as the auxiliary evaporator 120 or the auxiliary condenser 130. (S10)

If the auxiliary heat exchanger 110 is used as the auxiliary evaporator 120, the refrigerant from the condenser 40 passes through the flow path changing means 60, passes through the expansion valve 90 and passes through the auxiliary heat exchanger 110. After that, the refrigerant flow is changed to flow to the evaporator 100 via the flow path changing means 60 again,

Alternatively, when the auxiliary heat exchanger 110 is used as the auxiliary condenser 130, the refrigerant from the condenser 40 passes through the flow path changing means 60, passes through the auxiliary heat exchanger 110, and then expands the expansion valve 90. After coarse, the refrigerant flow is changed again to flow to the evaporator 100 via the flow path changing means 60 (S20).

First, when it is determined in the determination step (S10) to use the auxiliary heat exchanger 110 as the auxiliary evaporator 120, the heat pump draws heat from the outside.

Therefore, since the air is already partially heated by the auxiliary heat exchanger 110, the heating time of the air by the heater 25 can be shortened.

If it is determined in step S10 that the auxiliary heat exchanger 110 is used as the auxiliary condenser 130, heat may be released to the outside of the drum 20 to lower the temperature of the air inside the drum 20. .

That is, it is determined whether the auxiliary heat exchanger 110 is used as the auxiliary evaporator 120 or the auxiliary condenser 130 (S10), and the refrigerant flow is changed (S20), thereby increasing the temperature of the air in the drum 20. Alternatively, the temperature of the air in the drum 20 may be kept constant until the drying is completed.

Hereinafter, another preferred embodiment of the control method of the dryer 10 'according to the present invention will be described.

It is determined whether the auxiliary heat exchanger 110 is used as the auxiliary evaporator 120 or the auxiliary condenser 130 by measuring the temperature at the inlet of the drum 20. (S100)

That is, by measuring the temperature of the air at the inlet of the drum 20 by a temperature sensor (not shown), etc., the auxiliary heat exchanger 110, the auxiliary evaporator 120 that draws heat from the outside, or the auxiliary condenser that discharges heat to the outside. The refrigerant flow is changed to use at 130. (S200).

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be practiced by variously modifying or modifying the present invention without departing from the spirit and scope of the invention described in the claims. can do.

10,10 ': Dryer 15: Blowing fan
20 drum 25 heater
30: compressor 40: condenser
50: Euro 60: Euro change means
65: first gate of the channel changing means
70: second gate of the channel changing means
75: third gate of the channel changing means
80: fourth gate of the channel changing means
90 expansion valve 100 evaporator
110: auxiliary heat exchanger 120: auxiliary evaporator
130: auxiliary condenser 140: four sides

Claims (4)

A compressor in which the refrigerant is compressed;
A condenser connected with the compressor;
Flow path changing means connected to the condenser;
An expansion valve and an auxiliary heat exchanger and an evaporator connected to the flow path changing means,
When the auxiliary heat exchanger is used as an auxiliary evaporator, the refrigerant from the condenser passes through the flow path changing means, passes through the expansion valve, passes the auxiliary heat exchanger, and then passes through the flow path changing means to flow to the evaporator. The change means is opened and closed,
When the auxiliary heat exchanger is used as an auxiliary condenser, the refrigerant from the condenser passes through the flow path changing means, passes through the auxiliary heat exchanger, passes through the expansion valve, and then passes through the flow path changing means to flow to the evaporator. Dryer characterized in that the flow path changing means is opened and closed The method of claim 1,
The flow path changing means is a dryer, characterized in that the four sides The method of claim 1,
When the dryer is in the initial operating state, the dryer flow characterized in that for changing the refrigerant flow to use the auxiliary heat exchanger as a secondary evaporator The method of claim 1,
Characterized in that the refrigerant flow is changed to measure the drum inlet temperature of the dryer so that the auxiliary heat exchanger is used as an auxiliary evaporator or auxiliary condenser.

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